Pump, System With A Blood Pump And Method For Producing A Blood Pump

ABSTRACT

The invention relates to a blood pump made of titanium with a measuring device for determining flow based on acoustic flow measurement methods and a blood pump with a temperature sensor and/or a pressure sensor, and a system with a blood pump and an inlet cannula and/or an outlet connector and a method for producing a blood pump with a measuring device.

The invention relates to a blood pump made of titanium with a measuringdevice for to determine the flow based on acoustic flow measurementprocesses as well as a blood pump with a temperature sensor and/or apressure sensor as well as a system with a blood pump and an inletcannula and/or an outlet cannula with an outlet connector as well as aprocedure to produce a blood pump with a measurement device.

The task of this invention is to improve current state-of-the-art bloodpumps.

This is, in accordance with the first aspect of the invention, atitanium blood pump with a measurement device to determine flow, basedon acoustic flow measurement processes, whereby the measurement devicehas a measurement path with two coupling wedges with two transducersarranged with them, and the measurement device on a blood pump isarranged in such a way that an installation functions as a reflector.

An installation is any component that is arranged inside the pump. Anyinstallation can be used as a reflector, so that the measurement devicecan be freely located on the blood pump. In particular, no space free ofinstallations must be found for the measurement. This allows a morecompact design.

Acoustic flow measurement techniques permit the determination of theflow of fluids through analysis of the flow of modulated acoustic waves.In a paired sensor unit consisting transducers acting as alternatingtransmitters and receivers, it can principally assess the relativetransit time differences (in and against the flow direction), beamdeflection (shunting) and changes in phase, amplitude and frequency ofthe acoustic waves. Also, scattering effects can be evaluated. Soeffects, such as Doppler effects or entrainment effects can bedetermined. A preferred embodiment is to assess the relative transittime.

In order to achieve a measurement effect and to receive the transmittedsound waves, the transducers must be installed in a specific angle rangeto the flow. This is done by mounting on so-called coupling wedges. Thecoupling wedges are firmly connected to the blood pump. This ispreferably carried out by appropriate cut-outs on the pump housing. Avariant is the gluing or welding of coupling wedges to the desiredmeasurement points.

It is desirable for a blood pump to be able to determine the flow orvolume, without invasively accessing the flow stream. Thus it isespecially preferable not to have the transducers in contact with thebloodstream.

In a blood pump, the fluid being measured is blood. The blood pump isused to support or to replace the human heart. The blood pump satisfiesthe requirements for fully implantable medical devices.

Due to its corrosion resistance compared to other metals, titanium isused as the biomaterial for blood pumps. Other biocompatible materialscan be used in pump construction, such as ceramics like zirconium oxide.

Advantageously, the installation is a motor and flow is measured in anannular gap. It is thus possible to integrate flow measurement in themain blood pump section. This makes it possible to have a compactstructure, especially integrated wire management.

It is advantageous to have several measurement paths along thecircumference. This thus increases measurement accuracy. Thus variousspatial arrangements for the measurement paths, such as in the directionof the main axis or crossing the main axis or in the diagonal directionare possible. Thus even complex flow patterns can be detected.

In particular, the measurement paths can be arranged on opposite sites.A maximum distance between the measuring points can be achieved. Inaddition, an arrangement on the pump the housing is easily possible.

It is advantageous to place a sound barrier between the coupling wedges.This can minimise the transmission directly from one coupling wedge toanother. The sound is thus ideally mainly transmitted through the fluid.Also other measures can prevent direct transmission of the sound fromone coupling wedge to another coupling wedge, such as through fillingwith a damping medium, reducing the wall thickness of the pump housingbetween the coupling wedges or a milling of grooving in the wall betweenthe two coupling wedges. In particular, a combination of these measuresis advantageous.

It is advantageous if the measurement device is hermetically sealed in aspace via the pump environment. If the measurement device is insulatedfrom the environment in such a manner, a design as an implantable bloodpump is particularly possible.

It is advantageous if a grommet is arranged between the space and theinterior of the pump. In this way, all wires can be led in the interiorof the pump.

The grommet can be arranged along a longitudinal axis. Thus the the pathcan also show a radial skew.

A second independent aspect of the invention relates to a blood pumpwhich has a temperature sensor. The temperature sensor can determine thetemperature of the blood while the blood pump is operating. Hightemperatures lead to blood damage and should therefore be avoided.

A third independent aspect of the invention relates to a blood pumpwhereby it has an integrated pressure sensor. The pressure sensor caneither be an absolute pressure sensor or a differential pressure sensor.This pressure sensor can be integrated into a pump inlet and/or pumpoutlet. It can gather data on pressure conditions at both these sites onthe pump Through measurement at both locations, flow can determinedusing a stored characteristic map. In particular, a pressure sensor canbe integrated in the pump inlet when the pump inlet is placed directlyinto the ventricle without the interposition of a cannula. Thus anarrangement of the sensor on the outside of the pump inlet makes sensein order to measure the chamber pressure.

It is particularly advantageous here to have a combination of pressureand flow sensor technology on the pump in order to derive information onthrombi, suction or recovery. Due to the connection between the pump andthe sensor/cannula there is no installation at the cannula.

A fourth independent aspect of the invention relates to a blood pumpwhich has a first pressure sensor and a second pressure sensor, wherebythe first pressure sensor is arranged in such a way that it measurespressure in one heart chamber and the second pressure sensor is arrangedthat it measures pressure in a downstream vascular system. The heartchamber can be, for example, an atrium or a ventricle, while thedownstream vascular system can be, for example, an arterial system.

A fifth independent aspect of the invention is a system consisting of ablood pump and an inlet cannula, whereby the inlet cannula has apressure sensor and the pressure sensor is arranged particularly at thetip of the inlet cannula. This allows for separated exchange of thecomponents of the inlet cannula and the blood pump

It is advantageous if the pressure sensor on the tip of the inletcannula is arranged on the inside and/or the outside of the tip. It isthereby possible to measure the pressure directly in the chamber if itis mounted on the outside of the cannula, whereby a sensor placed on theinside of the tip of the inlet cannula measures the pressure within thepump system. This is possible when placing the pump in the ventricle aswell as in the atrium.

A further advantage is when an additional flow sensor is arranged in thesystem. For example, this sensor can be placed on the inlet cannula.Flow measurement is also possible in a decoupled fashion. Also placementof a flow sensor on the outlet cannula or outlet connector is possible.This flow measurement is usually easier possible, since the flow channelis relatively large. This flow sensor technology may be providedadditionally to the flow sensor technology integrated into the pump, oralternatively to it.

A further independent aspect of the invention is that the outlet cannulais equipped with an outlet connector in which a pressure sensor isplaced. This allows for pressure measurement at the pump outlet. Theintegration of the sensor in the periphery (inlet cannula, outletcannula with an outlet connector) creates a separation of the complextechnical entities of pump and sensor units. This results in riskminimisation during production. A change of the pump during treatment isnot excluded. By a separating the components, one need not change thesensors.

Pressure measurement of chamber pressure as well as systemic bloodpressure in the downstream vascular system provide not only monitoringof the technical system, but also makes therapeutic monitoring possible.

A final aspect of the invention relates to a procedure to produce ablood pump with a measuring device, wherein the coupling wedges aremilled from the pump housing. This means that further attachment of thecoupling wedges is not needed because they are automatically integratedinto the pump housing. Advantageously, the coupling wedges are therebypositioned so that that a measurement occurs in the annular gap.

A further advantage is that if a coupling wedge has an enclosing wallmilled from the pump housing. This has the advantage that the couplingwedges from the three spatial directions are surrounded by a wall. Theyare therefore protected in these three spatial directions, and the wallneed not be connected with the pump housing. Thus concomitant mountingelectronic components of the measurement path can be done from above.

Further, one can drill from within the walls to the inside of the pump.Later, wires can be guided in this drill hole which lead from the insideof the wall to the inside of the pump.

The drill hole can be drilled in an axial direction. Thus, the wires scan be guided sidewards or in the direction of flow.

Finally, a cover can be installed on the wall, so that the couplingwedges are hermetically sealed off from the pump environment. Thus themeasurement device is sealed off from influences from the outside, andis in particular water-sealed.

Thus the cover can be welded. This would produce a lasting, sealedconnection.

The invention will be explained in more detail with reference todrawings and implementation examples below. These show:

FIGS. 1 a and 1 b a schematic presentation of a longitudinal sectionthrough a blood pump with a measurement device and a cross-sectionthrough the blood pump with the measuring device.

FIGS. 2 a and b a schematic representation of a transverse andlongitudinal section through a blood pump with a measuring device withtwo measuring paths,

FIGS. 3 a, b and c a schematic presentation of a longitudinal sectionthrough a blood pump with a measuring device, a topview of the bloodpump with the measurement device and a three-dimensional side view ofthe blood pump with the measuring device,

FIGS. 4 a, b and c a schematic representation of a longitudinal sectionthrough a blood pump with a measuring device with two measuring paths,of which one has a sound barrier, a topview of the blood pump with themeasuring device with two with two measuring paths of which one has asound barrier and a three-dimensional side view of the blood pump withthe measuring apparatus with two measuring paths of which one has asound barrier,

FIG. 5 a schematic representation of a cannula system with a blood pumpwith an inlet and an outlet cannula with an outlet connector withintegrated pressure measurement at the pump inlet and outlet,

FIG. 6 a schematic representation of a cannula system with a blood pumpwith an inlet and an outlet cannula with an outlet connector withintegrated pressure measurement in the inlet cannula and an outletconnector,

FIG. 7 a schematic representation of a system with a blood pump havingan inlet cannula and an outlet cannula with pressure measurementintegrated into the pump at the pump inlet and outlet with pressuremeasurement integrated in the inlet cannula and the outlet connector.

FIG. 8 a schematic representation of a blood pump in its operationlocation in the blood system between the atrium and arterial system,

FIG. 9 a schematic representation of a system with a blood pump with aninlet and an outlet cannula with an outlet connector r with pressuremeasurement integrated into the pump inlet and outlet, here withintegrated pressure measurement in the inlet cannula and an outletconnector as well as an integrated flow and temperature sensortechnology,

FIG. 10 a schematic representation of a blood pump in its operationlocation in the blood system between the ventricle and the arterialsystem,

FIG. 11 a schematic representation of a blood pump at its operationlocation in the blood system between the ventricle and arterial system,whereby the pump inlet is placed directly without use of an intermediatecannula in the heart chamber,

FIG. 12 a schematic representation of a blood pump on location in theblood system between the atrium and arterial system, whereby the pumpinlet is directly placed without use of an intermediate cannula in theheart chamber,

FIG. 13 a schematic view of a section of the tip of an inlet cannula and

FIG. 14 a schematic representation of a cross-section of an outletcannula with an outlet connector.

In a blood pump 1, a measurement device can be provided, as shown inFIGS. 1 a and 1 b, which allows for integrated flow measurement in theannular gap 3. The measuring device consists of a measuring path 4 withtwo coupling wedges 5, 6 and transducers 7, 8 arranged on these. Themeasuring apparatus 2 is arranged in a hermetically sealed box 9,consisting of a wall 10 and a cover 11. A side wall of the wall 10 has adrill hole 12, through which for operation and control of the measuringdevice 2 wires (not pictured) are guided sideways and to the inside ofthe pump.

In production, the coupling wedges 5 and 6 and the wall 10 of the box 9are milled from the pump housing 13. Before the cover 11 is applied andsealed, the transducers 7, 8 are first welded and assembled and theappropriate wires (not pictured) for the operation and control of thetransducers 7, 8 are led through the drill hole 12. Thus installationfrom the top is possible. Only after application and welding of thecover 11 is the flow measuring unit 2 hermetically sealed. In operation,the blood flows through the pump 1, shown schematically by the arrow 14at the pump inlet 15 into the blood pump 1 and flows over the rotor 16and through the annular gap 3 between the motor 17 and the pump housing13. In order to measure the flow rate or the volume flow rate of thisblood flow 14 in the annular gap, the measuring device 2 is placed forintegrated flow measurement over the annular gap 3. In operationalternately the transducer 7 or the transducer 8 sends sound waves whichmove through the blood flow in the annular gap 3 and are reflected onthe motor 17, so that the other transducer 8 or 7 receives them. Fromthe data obtained, the flow rate or the volume flow rate can then bedetermined in the annular gap 3. In order to keep a direct transferbetween the coupling wedges 5 and 6 as low as possible, the piece of thewall 18 of the pump housing 13 located between the coupling wedges iskept as thin as thin as possible.

As shown in FIG. 2, a blood pump 21 can have a measuring device withseveral measuring paths. Thus two flow sensors 22, 23 are arrangedopposite of one another to allow simultaneous flow measurement over theannular gap 24, one above the motor 25 and one below the motor 25. Alsohere, when operating, the blood flows through the pump inlet 26 over therotor 27 through the annular gap 24 between the motor 25 and the pumphousing 28, to then leave the blood pump 21 through the pump outlet 29.Thus the flow measurement is done by the flow sensors 22 and 23 each atannular gap 24 in which the flow is determined.

A measurement path 32 on the blood pump 31 in FIG. 3 a-c, consists oftwo coupling wedges 33 34 which are not surrounded by a box milled fromthe pump housing. The measuring path 32 is positioned in axialdirection. The coupling wedges 33, 34 are however again milled from thepump housing 35. The coupling wedges 33, 34 each show a coupling angleα,β of 30° perpendicular to the pump housing 35. The outside diameter ofthe pump housing 35 in the area of the motor 36 is about 14 mm, theinner diameter is about 11 mm, whereas the diameter of the motor itselfis approximately 8.5 mm. The annular gap 37 thus has a width of about1.25 mm. The coupling wedges 33 and 34 are arranged at a distance ofabout 1.8 mm and each shows in flow direction a length of 4 mm, as wellas a width of 4 mm perpendicular to the flow direction. The distancebetween the two tips 38 and 39 of the two coupling wedges 33, 34 isapproximately 7.8 mm. Offset by 90°, a second measuring path 40 ispositioned with respective components.

Also, on the blood pump 41 in FIG. 4 a-c the measuring path 42,consisting of two coupling wedges 43 and 44 is placed in a radialorientation. This transducer has three sound walls 45, 46 and 47, whichprevent transfer of sound from one coupling wedge directly to the nextcoupling wedge. The number of sound walls is however variable. Also asecond radial measurement path 48 without acoustic breaker is provided.The coupling wedges 49 and 50 each on the outside show a coupling angleα,β of 30° to the perpendicular.

When installed a blood pump 61 is integrated into a pump system 60, seeFIG. 5. Thus the pump is connected with an inlet cannula 62 and anoutlet cannula with an outlet connector 63. The inlet cannula 62 isconnected by a tip 65 to the heart wall 66. The blood flows over a tip65 through the inlet cannula 62 into the pump inlet 67, where it ispumped through the motor 68 operated with the rotor 69 through the bloodpump 61 to exit again at the pump outlet 70. To this, an outletconnector 64 with the outlet cannula 63 is attached. The pressure isdetermined at the pressure sensor 71 at the pump inlet 67 and thepressure sensor 72 at the pump outlet 70 at both these locations in thesystem. Thus, not only monitoring of the technical system, but alsotherapeutic monitoring is possible.

Alternatively, as shown in the blood pump system 80 in FIG. 6, thepressure can be measured at the tip 83 of the inlet cannula 82, and theoutlet connector 89 of the outlet cannula 90 by the relevant sensors 91,92 and 93. Thus sensor 91 measures the pressure distal to the heart wall84 directly in the atrium, the sensor 92 measures the pressure withinthe pump system 80 at the pump inlet 85, and the sensor 93 measures thepressure within the pump system 80 at the pump outlet 88. The blood pump81 also includes a rotor 86 and a motor 87, through which the blood istransported.

Also, combined flow and pressure measurement is possible, as is shown inthe blood pump system 100 with the blood pump 101, shown in FIG. 7. Herethe blood pump 101 with rotor 102 and motor 103 has a flow sensor 104and pressure sensors 105, 106 at the pump inlet 107 and the pump outlet108. In addition, also pressure sensors 109, 111 are provided at the tip110 of the inlet cannula 112. Here, the pressure sensor 111 is placed onthe inside of the tip 110 and thus measures the pressure at that point,whereas the pressure sensor 109 is distal to the heart wall 113 on theoutside of the tip 110, and thus measures pressure in the atrium. Inaddition, the outlet cannula 114 at the outlet connector 115 includes afurther pressure sensor 116, which determines the pressure at thispoint. There are sensors integrated in this system in the blood pump 101at its inlet 107 and outlet 108, as well as in the tip 110 of the inletcannula 112 and the outlet connector 115 of the outlet cannula 114. Thusthere is at least one partial separation of the complex technical unitsof the pump 101 and the sensors. This minimises risk during productionand during treatment switching of the pump 101 is not excluded. A changeof the sensor technology is then only partially necessary.

Altogether, such a system 121 measures the pressure at four places onthe pump system 121 consisting of the blood pump 122, inlet cannula 123and outlet cannula 124, as presented in the operating condition in theblood system in FIG. 8. Namely, the pressure directly in the atrium 125,the pressure at the pump inlet 126, the pressure at the pump outlet 127and the pressure at entry to the aorta at the location 128. Thus thepressure at pump inlet 126 can be measured by in the blood pump 122integrated sensors, as well as by a sensor integrated in the inside ofthe inlet cannula 123. Also the pressure at pump outlet 127 can bemeasured by a sensor integrated in the blood pump 122, as well asthrough a sensor integrated into the outlet sensor. Furthermore, thearrangement of a sensor at the tip of the outlet connector is alsopossible on the outside in order to measure aortal pressure.

As shown in FIG. 9, one could also imagine a blood pump system 131 whichunites all sensor types. Thus the blood pump 132 includes a flow sensor133 as well as a temperature sensor 134. Furthermore, pressure sensors137, 138 are integrated in the pump inlet 135 as well as in the pumpoutlet 136. The inlet cannula 139 also has a flow sensor 140. Inaddition, a pressure sensor 142 is integrated into a cannula tip 141 onthe inside of the tip 141 and a pressure sensor 143 is provided on theoutside of the tip 141 distal to the heart wall 144. In addition, theoutlet cannula 145 in the outlet connector 146 has a pressure sensor147. Thus, combined flow and pressure measurement is possible, which areboth incorporated into the blood pump 132. and decoupled from the bloodpump in the inlet cannula 139 and outlet cannula 145 at differentlocations.

As an alternative to the location presented in FIG. 8 in the atrium 152,one can also implant directly into the ventricle 153. The blood pumpsystem 151 consisting of blood pump 154 with inflow cannula 155 andoutlet cannula 156 may then make the measurements by the appropriatesensors at the points indicated.

In addition, it is possible that one can place a pump system 161 or 171,as shown in FIGS. 11 and 12, so that the pump inlet 162, 172 of theblood pump 163, 173 can be placed directly into a heart chamber withoutinterposition of a cannula, namely in the ventricle 164 or in the atrium174. The outlet cannula 165, 175 is introduced into the aorta 166, 176.One of the sensors placed on the outside of the blood inlet 162, 172(not pictured) can thus measure the chamber pressure. Also further flowand pressure sensors (not pictured) provide relevant data, such aspressure in the arterial system.

In detail, the inlet cannula 181, as is shown in FIG. 13, on theheart-facing side of the inlet cannula 181, has a tip 182 to which thecannula 183 is attached. The tip 182 is connected to the cannula 183 andengages at its tip with the heart wall 184. In addition, a pressuresensor 185 is integrated into the tip 182.

An outlet cannula 191, as shown in FIG. 14, has an outlet connector 192,over which the graft or the outlet 193 is connected to the blood pump194. A pressure sensor 195 is integrated into the outlet connector 192.

1. A blood pump comprising titanium and a measuring device to determineflow based on acoustic flow measurement processes, whereby the measuringdevice comprises a measuring path with two coupling wedges with twotransducers placed on these, wherein the measuring device is attached tothe blood pump such that an installation functions as a reflector. 2.The blood pump of claim 1, wherein the installation is a motor and thatthe flow is measured in an annular gap.
 3. The blood pump of claim 1,wherein along the circumference, several measuring paths are arranged.4. The blood pump of claim 3, wherein the measurement paths are placedon opposite sides.
 5. The pump of claim 1, further comprising a soundwall arranged between the coupling wedges.
 6. The blood pump of claim 1,wherein the measuring device is sealed hermetically in a space via thepump environment.
 7. The blood pump of claim 6, further comprising agrommet arranged between the space and the inside of the pump.
 8. Theblood pump claim 7, wherein the grommet is arranged along thelongitudinal axis.
 9. The blood pump of claim 1, further comprising atemperature sensor.
 10. The blood pump of claim 1, further comprising anintegrated pressure sensor.
 11. The blood pump of claim 10, wherein thepressure sensor is placed at a pump inlet and/or a pump outlet.
 12. Theblood pump of claim 10, which comprises a first pressure sensor and asecond pressure sensor, wherein the first pressure sensor is arranged insuch a way that it measures pressure in one heart chamber, and thesecond pressure sensor is arranged in such a way that it measurespressure in the downstream vascular system.
 13. A system comprising theblood pump of claim 1, and an inlet cannula comprising a pressure sensorarranged at the tip of the inlet cannula.
 14. The system of claim 13,wherein the pressure sensor is placed on the inside and/or the outsideof the tip.
 15. The system of claim 13, further comprising a flow sensorarranged at the inlet cannula.
 16. (canceled)
 17. The system of claim12, further comprising an outlet cannula with an outlet connector,wherein the outlet connector has a pressure sensor.
 18. A process forthe preparation of the blood pump of claim 1, comprising cutting thecoupling wedges from a pump housing.
 19. The process of claim 18,wherein a wall which encloses one of the coupling wedges is milled fromthe pump housing.
 20. The process of claim 19, wherein a drill hole isdrilled from inside the wall to the interior of the pump.
 21. Theprocess of claim 20, wherein the drill hole is drilled in an axialdirection.
 22. The process of claim 19, further comprising placing acover on the wall, so that coupling wedges are hermetically sealed fromthe pump environment.
 23. The process of claim 22, wherein the cover iswelded to the wall.
 24. The system of claim 17, wherein the flow sensoris arranged at the outlet connector.